Water flows through a 0.007m2 pipe at a speed of 4.5m/s. How much water mass (kg) will flow in 30 seconds? Water has a density of 1000kg/m3 . ( ρvA = m t )
Water flows through a 0.007m2 pipe at a speed of 4.5m/s. How much water mass (kg)...
Water (density = 1000 kg/m3) flows through a 0.30-m-diameter pipe at 1.5m/s. What is the mass flow rate of water?
Water flows with mass flow rate 0.0566kg/s through a pipe with diameter 30mm and length 600m. Find the pressure drop across the pipe if the friction factor is 8/Re, Density of water=1000Kg/m3 and the viscosity of water=0.0018Ns/m2 Select one: a. 3072 N/m2 O b. 3101 N/m2 0 c. 3111 N/m2 O d. 3001 N/m2 e. 3022 N/m2
Water (density = 1.0 x 103 kg/m3 ) flows through a horizontal tapered pipe. At the wide end its speed is 4.0 m/s. The difference in pressure between the two ends is 4.5 x103 Pa. The speed of the water at the narrow end is: A. 2.6 m/s B. 3.2 m/s C. 4.0 m/s D. 4.5 m/s E. 5.0 m/s
Water travels through a pipe at 9.78 m/s. The pipe contracts from a crossectional area of 1.4 m2 to an area of 0.156 m2. What is the speed of the water in the second part of the pipe in m/s? How much is the pressure change in KPa as the pipe contracts? The density of water is 1000 kg/m3. Enter a positive value for an increase in pressure, a negative value for a decrease.
Part 1 Correct. Water flows through a horizontal, pipe bend as is illustrated in the figure below. The flow cross section area is constant at a value of 9000 mm2. The flow velocity everywhere in the bend is 15 m/s. The pressures at the entrance and exit of the bend are 210 and 149 kPa, respectively. Calculate the horizontal (x and y) components of the anchoring force needed to hold the bend in place (a) What is the density of...
Water flows at speed of 6 m/s through a horizontal pipe of diameter 3.5 cm. The gauge pressure P1 of the water in the pipe is 1.7 atm. A short segment of the pipe is constricted to a smaller diameter of 2.4 cm . What is the gauge pressure of the water flowing through the constricted segment? Atmospheric pressure is 1.013 × 10^5 Pa. The density of water is 1000 kg/m^3 . The viscosity of water is negligible. Answer in...
1. A liquid with a density of 750.0 kg/m3 flows through a 2.50 cm ID pipe at a rate of 17.5 L/min. a. Determine the mass flow rate in kg/s. (5 marks) b. Determine the velocity of the liquid in m/s. (5 marks)
Water flows in the horizontal pipe shown in the figure. At point A the area is 26.0 cm2 and the speed of the water is 2.20 m/s. At B the area is 15.0 cm2. The fluid in the manometer is mercury, which has a density of 13,600 kg/m3. We can treat water as an ideal fluid having a density of 1000 kg/m3. What is the manometer reading h? Question 10 (1 point) Water flows in the horizontal pipe shown in...
Water at 20°C flows at 0.08 m3/s through a pipe and is metered by a 12 cm diameter long-radius flow nozzle (d = 12 cm). If the pressure drop across the nozzle is 25 kPa, what is the diameter of the pipe (D)? Use: Pwater = 998 kg/m3; Hwater = 0.001 kg/m-s. Express your answer in centimeters (cm). D
A liquid of density 1.39 × 103 kg/m3 flows steadily through a pipe of varying diameter and height. At location 1 along the pipe the flow speed is 9.67 m/s and the pipe diameter is 11.5 cm. At location 2 the pipe diameter is 14.9 cm. At location 1 the pipe is 8.31 m higher than it is at location 2. Ignoring viscosity, calculate the difference between the fluid pressure at location 2 and the fluid pressure at location 1.